Molecular characterization of MARTA1, a protein interacting with the dendritic targeting element of MAP2 mRNAs

In neurones, the somatodendritic microtubule-associated protein 2 regulates the stability of the dendritic cytoskeleton. Its extrasomatic localization appears to be a multicausal mechanism that involves dendritic mRNA trafficking, a process that depends on a dendritic targeting element in the 3' untranslated region. Two rat MAP2-RNA trans-acting proteins, MARTA1 and MARTA2, exhibit specific high-affinity binding to the dendritic targeting element. We have now affinity-purified MARTA1 from rat brain. Analysis of proteolytic peptides revealed that rat MARTA1 is the orthologue of the human RNA-binding protein KSRP. Rat MARTA1 is a 74-kDa protein that contains four putative RNA-binding domains and is 98% identical to human KSRP. Both purified rat MARTA1 and human KSRP preferentially bind to the dendritic targeting element, but do not strongly interact with other investigated regions of mRNAs encoding microtubule-associated protein 2 and alpha-tubulin. In rat brain neurones and cultured neurones derived from superior cervical ganglia, MARTA1 is primarily intranuclear, but is also present in the somatodendritic cytoplasm. Thus, MARTA1 may play a role in nucleocytoplasmic mRNA targeting.     

The FTLD risk factor TMEM106B and MAP6 control dendritic trafficking of lysosomes

TMEM106B is a major risk factor for frontotemporal lobar degeneration with TDP‐43 pathology. TMEM106B localizes to lysosomes, but its function remains unclear. We show that TMEM106B knockdown in primary neurons affects lysosomal trafficking and blunts dendritic arborization. We identify microtubule‐associated protein 6 (MAP6) as novel interacting protein for TMEM106B. MAP6 over‐expression inhibits dendritic branching similar to TMEM106B knockdown. MAP6 knockdown fully rescues the dendritic phenotype of TMEM106B knockdown, supporting a functional interaction between TMEM106B and MAP6. Live imaging reveals that TMEM106B knockdown and MAP6 overexpression strongly increase retrograde transport of lysosomes in dendrites. Downregulation of MAP6 in TMEM106B knockdown neurons restores the balance of anterograde and retrograde lysosomal transport and thereby prevents loss of dendrites. To strengthen the link, we enhanced anterograde lysosomal transport by expressing dominant‐negative Rab7‐interacting lysosomal protein (RILP), which also rescues the dendrite loss in TMEM106B knockdown neurons. Thus, TMEM106B/MAP6 interaction is crucial for controlling dendritic trafficking of lysosomes, presumably by acting as a molecular brake for retrograde transport. Lysosomal misrouting may promote neurodegeneration in patients with TMEM106B risk variants.     

Poster Sessions CP05: Intracellular Transport and Vesicle Trafficking. MBP mRNA trafficking factor HNRNP A2 interacts with microtubules binding protein TOG

HnRNP A2 is an RNA trafficking protein that binds to a specific cis‐acting RNA trafficking element (A2RE) in myelin basic protein RNA and other transported RNAs. A2RE/hnRNPA2 determinants mediate several different steps in RNA trafficking including granule assembly, transport to the plus ends of microtubules and translational activation. A yeast two hybrid screen designed to identify proteins that interact with hnRNP A2 selected a clone corresponding to the carboxyl terminal portion of TOG (tumor overexpressed gene), a microtubule‐associated protein that regulates microtubule dynamics. Co‐immunostaining of oligodendrocytes with antibody to hnRNPA2 and TOG revealed extensive colocalization of TOG with hnRNP A2 granules in the dendrites. A small population of hnRNP A2 granules lacked TOG and some regions of TOG staining lacked hnRNP A2. In oligodendrocytes injected with fluorescent A2RE RNA and stained for TOG, granules containing fluorescent RNA colocalized with TOG. Co‐injection of anti‐TOG antibody with fluorescent A2RE RNA decreased colocalization with TOG and increased transport of the injected RNA. These observations suggest that molecular interaction between hnRNP A2 and TOG serves to anchor A2RE mRNAs/hnRNPA2 granules at plus ends of microtubules. Acknowledgements: Supported by NIH NS19943 (EB) and NS15190 (JHC), and NMSS RG2843 (EB).     

Polypyrimidine tract‐binding protein is required for the repression of gene expression by all‐trans retinoic acid

All‐trans retinoic acid is a key regulator of early development. High concentrations of retinoic acid interfere with differentiation and migration of neural crest cells. Here we report that a dinucleotide repeat in the cis‐element of Snail2 (previously known as Slug) gene plays a role in repression by all‐trans retinoic acid. We analyzed the cis‐acting regulatory regions of the Xenopus Snail2 gene, whose expression is repressed by all‐trans retinoic acid. The analysis identified a TG/CA repeat as a necessary element for the repression. By performing a yeast one‐hybrid screen, we found that a polypyrimidine tract‐binding protein (PTB), which is known to be a regulator of the alternative splicing of pre‐messenger RNA, binds to the TG/CA repeat. Overexpression and knockdown experiments for PTB in HEK293 cells and Xenopus embryos indicated that PTB is required for repression by retinoic acid. The green fluorescent protein‐PTB fusion protein was localized in the nucleus of 293T cells. In situ hybridization for PTB in Xenopus embryos showed that PTB is expressed at the regions including neural crest at the early stages. Our results indicate that PTB plays a role in the repression of gene expression by retinoic acid through binding to the TG/CA repeats.     

Cytoplasmic polyadenylation element-like sequences are involved in dendritic targeting of BDNF mRNA in hippocampal neurons

Several mRNAs are known to be targeted to dendrites in hippocampal neurons. In this study, we show that brain-derived neurotrophic factor (BDNF) mRNA has two distinct cis-acting dendritic targeting elements in the short 3′ untranslated region (UTR): a constitutive element and an activity-dependent one. Moreover, deletion of serial cytoplasmic polyadenylation element (CPE)-like sequences in the short 3′UTR suppressed both constitutive and activity-dependent dendritic targeting. In addition to the interaction with cytoplasmic polyadenylation element binding protein-1 (CPEB-1), depolarization enhanced CPEB-1 recruitment to the activity-dependent targeting element. These results suggest that CPE-like sequences are involved in the activity-dependent as well as constitutive dendritic targeting of BDNF mRNA.     

Microtubule‐binding protein doublecortin‐like kinase 1 (DCLK1) guides kinesin‐3‐mediated cargo transport to dendrites

In neurons, the polarized distribution of vesicles and other cellular materials is established through molecular motors that steer selective transport between axons and dendrites. It is currently unclear whether interactions between kinesin motors and microtubule‐binding proteins can steer polarized transport. By screening all 45 kinesin family members, we systematically addressed which kinesin motors can translocate cargo in living cells and drive polarized transport in hippocampal neurons. While the majority of kinesin motors transport cargo selectively into axons, we identified five members of the kinesin‐3 (KIF1) and kinesin‐4 (KIF21) subfamily that can also target dendrites. We found that microtubule‐binding protein doublecortin‐like kinase 1 (DCLK1) labels a subset of dendritic microtubules and is required for KIF1‐dependent dense‐core vesicles (DCVs) trafficking into dendrites and dendrite development. Our study demonstrates that microtubule‐binding proteins can provide local signals for specific kinesin motors to drive polarized cargo transport.     

Identification of an intronic splicing regulatory element involved in auto‐regulation of alternative splicing of SCL33 pre‐mRNA

In Arabidopsis, pre‐mRNAs of serine/arginine‐rich (SR) proteins undergo extensive alternative splicing (AS). However, little is known about the cis‐elements and trans‐acting proteins involved in regulating AS. Using a splicing reporter (GFP–intron–GFP), consisting of the GFP coding sequence interrupted by an alternatively spliced intron of SCL33, we investigated whether cis‐elements within this intron are sufficient for AS, and which SR proteins are necessary for regulated AS. Expression of the splicing reporter in protoplasts faithfully produced all splice variants from the intron, suggesting that cis‐elements required for AS reside within the intron. To determine which SR proteins are responsible for AS, the splicing pattern of the GFP–intron–GFP reporter was investigated in protoplasts of three single and three double mutants of SR genes. These analyses revealed that SCL33 and a closely related paralog, SCL30a, are functionally redundant in generating specific splice variants from this intron. Furthermore, SCL33 protein bound to a conserved sequence in this intron, indicating auto‐regulation of AS. Mutations in four GAAG repeats within the conserved region impaired generation of the same splice variants that are affected in the scl33 scl30a double mutant. In conclusion, we have identified the first intronic cis‐element involved in AS of a plant SR gene, and elucidated a mechanism for auto‐regulation of AS of this intron.     

Involvement of α2‐antiplasmin in dendritic growth of hippocampal neurons

The α2‐Antiplasmin (α2AP) protein is known as a principal physiological inhibitor of plasmin, but we previously demonstrated that it acts as a regulatory factor for cellular functions independent of plasmin. α2AP is highly expressed in the hippocampus, suggesting a potential role for α2AP in hippocampal neuronal functions. However, the role for α2AP was unclear. This study is the first to investigate the involvement of α2AP in the dendritic growth of hippocampal neurons. The expression of microtubule‐associated protein 2, which contributes to neurite initiation and neuronal growth, was lower in the neurons from α2AP^?/? mice than in the neurons from α2AP^+/+ mice. Exogenous treatment with α2AP enhanced the microtubule‐associated protein 2 expression, dendritic growth and filopodia formation in the neurons. This study also elucidated the mechanism underlying the α2AP‐induced dendritic growth. Aprotinin, another plasmin inhibitor, had little effect on the dendritic growth of neurons, and α2AP induced its expression in the neurons from plaminogen^?/? mice. The activation of p38 MAPK was involved in the α2AP‐induced dendritic growth. Therefore, our findings suggest that α2AP induces dendritic growth in hippocampal neurons through p38 MAPK activation, independent of plasmin, providing new insights into the role of α2AP in the CNS.     

mRNA distribution within dendrites: Relationship to afferent innervation

The majority of neuronal mRNAs are confined to cell bodies, but a few mRNAs are present at high levels in dendrites. Here we report an initial analysis of the relationship between afferent innervation and the distribution of mRNA within dendritic fields. In situ hybridization techniques were used to compare the subcellular distribution of dendritic mRNAs in principal neurons of the hippocampal formation in vivo. The mRNA encoding the α subunit of calcium/calmodulin dependent protein kinase II (CAMII kinase) was present at high levels throughout the layers that contain the dendrites of hippocampal pyramidal cells and dentate granule cells. In contrast, the mRNA encoding the high molecular weight microtubule-associated protein MAP2 had a more limited distribution. In the dentate gyrus, labeling for MAP2 was present in a discrete band in the lamina containing proximal dendrites and decreased to low levels in laminae containing distal dendrites. This laminar pattern resembles the distinct terminations of the commissural/associational projection (high MAP2 labeling) and the entorhinal projection (lower MAP2 labeling) upon dendrites of granule cells. To determine if the differential distribution of dendritic mRNAs was regulated by either the presence or activity of afferents, we evaluated mRNA distribution in the dentate molecular layer following (1) removal of the entorhinal input by lesions of the entorhinal cortex or (2) prolonged delivery of potentiating stimulation to entorhinal afferents. Denervation led to modest decreases in the levels of mRNAs for both CAMII and MAP2 but did not lead to detectable alterations in mRNA distribution. Also, prolonged stimulation did not lead to detectable alterations in MAP2 or CAMII mRNA distribution, although such stimulation clearly elevated the expression of mRNA for glial fibrillary acidic protein (GFAP). © 1995 John Wiley & Sons, Inc.     

The Function of Circadian RNA‐Binding Proteins and Their cis‐Acting Elements in Microalgae

An endogenous clock regulates the temporal expression of genes/mRNAs that are involved in the circadian output pathway. In the bioluminescent dinoflagellate Gonyaulax polyedra circadian expression of the luciferin‐binding protein (LBP) is controlled at the translational level. Thereby, a clock‐controlled RNA‐binding protein, called circadian controlled translational regulator (CCTR), interacts specifically with an UG‐repeat, which is situated in the lbp 3^′ UTR. Its binding activity correlates negatively with the amount of LBP during a circadian cycle. In the green alga Chlamydomonas reinhardtii, a clock‐controlled RNA‐binding protein (CHLAMY 1) was identified, which represents an analog of the CCTR from the phylogenetically diverse alga G. polyedra. CHLAMY 1 binds specifically to the 3^′ UTRs of several mRNAs and recognizes them all via a common cis‐acting element, composed of at least seven UG‐repeats. The binding strength of CHLAMY 1 is strongest to mRNAs, whose products are key components of nitrogen metabolism resulting in arginine biosynthesis as well as of CO₂ metabolism. Since temporal activities of processes involved in nitrogen metabolism have an opposite phase than CHLAMY 1 binding activity, the protein might repress the translation of the cognate mRNAs.     

Histone gene expression and histone mRNA 3' end structure in <Emphasis Type="Italic">Caenorhabditis elegans</Emphasis>

Background  

Histone protein synthesis is essential for cell proliferation and required for the packaging of DNA into chromatin. In animals, histone proteins are provided by the expression of multicopy replication-dependent histone genes. Histone mRNAs that are processed by a histone-specific mechanism to end after a highly conserved RNA hairpin element, and lack a poly(A) tail. In vertebrates and Drosophila, their expression is dependent on HBP/SLBP that binds to the RNA hairpin element. We showed previously that these cis and trans acting regulators of histone gene expression are conserved in C. elegans. Here we report the results of an investigation of the histone mRNA 3' end structure and of histone gene expression during C. elegans development.     

DCLK1 phosphorylates the microtubule‐associated protein MAP7D1 to promote axon elongation in cortical neurons

Doublecortin‐like kinase 1 (DCLK1) is a member of the neuronal microtubule‐associated doublecortin (DCX) family and functions in multiple stages of neural development including radial migration and axon growth of cortical neurons. DCLK1 is suggested to play the roles in part through its protein kinase activity, yet the kinase substrates of DCLK1 remain largely unknown. Here we have identified MAP7D1 (microtubule‐associated protein 7 domain containing 1) as a novel substrate of DCLK1 by using proteomic analysis. MAP7D1 is expressed in developing cortical neurons, and knockdown of MAP7D1 in layer 2/3 cortical neurons results in a significant impairment of callosal axon elongation, but not of radial migration, in corticogenesis. We have further defined the serine 315 (Ser 315) of MAP7D1 as a DCLK1‐induced phosphorylation site and shown that overexpression of a phosphomimetic MAP7D1 mutant in which Ser 315 is substituted with glutamic acid (MAP7D1 S315E), but not wild‐type MAP7D1, fully rescues the axon elongation defects in Dclk1 knockdown neurons. These data demonstrate that DCLK1 phosphorylates MAP7D1 on Ser 315 to facilitate axon elongation of cortical neurons. © 2016 Wiley Periodicals, Inc. Develop Neurobiol 77: 419–437, 2017     

X‐ray and Cryo‐EM structures reveal mutual conformational changes of Kinesin and GTP‐state microtubules upon binding

The molecular motor kinesin moves along microtubules using energy from ATP hydrolysis in an initial step coupled with ADP release. In neurons, kinesin‐1/KIF5C preferentially binds to the GTP‐state microtubules over GDP‐state microtubules to selectively enter an axon among many processes; however, because the atomic structure of nucleotide‐free KIF5C is unavailable, its molecular mechanism remains unresolved. Here, the crystal structure of nucleotide‐free KIF5C and the cryo‐electron microscopic structure of nucleotide‐free KIF5C complexed with the GTP‐state microtubule are presented. The structures illustrate mutual conformational changes induced by interaction between the GTP‐state microtubule and KIF5C. KIF5C acquires the ‘rigor conformation’, where mobile switches I and II are stabilized through L11 and the initial portion of the neck‐linker, facilitating effective ADP release and the weak‐to‐strong transition of KIF5C microtubule affinity. Conformational changes to tubulin strengthen the longitudinal contacts of the GTP‐state microtubule in a similar manner to GDP‐taxol microtubules. These results and functional analyses provide the molecular mechanism of the preferential binding of KIF5C to GTP‐state microtubules.     

Transport of fragile X mental retardation protein via granules in neurites of PC12 cells

Lack of fragile X mental retardation protein (FMRP) causes fragile X syndrome, a common form of inherited mental retardation. FMRP is an RNA binding protein thought to be involved in translation efficiency and/or trafficking of certain mRNAs. Recently, a subset of mRNAs to which FMRP binds with high affinity has been identified. These FMRP-associated mRNAs contain an intramolecular G-quartet structure. In neurons, dendritic mRNAs are involved in local synthesis of proteins in response to synaptic activity, and this represents a mechanism for synaptic plasticity. To determine the role of FMRP in dendritic mRNA transport, we have generated a stably FMR1-enhanced green fluorescent protein (EGFP)-transfected PC12 cell line with an inducible expression system (Tet-On) for regulated expression of the FMRP-GFP fusion protein. After doxycycline induction, FMRP-GFP was localized in granules in the neurites of PC12 cells. By using time-lapse microscopy, the trafficking of FMRP-GFP granules into the neurites of living PC12 cells was demonstrated. Motile FMRP-GFP granules displayed two types of movements: oscillatory (bidirectional) and unidirectional anterograde. The average velocity of the granules was 0.19 micro m/s with a maximum speed of 0.71 micro m/s. In addition, we showed that the movement of FMRP-GFP labeled granules into the neurites was microtubule dependent. Colocalization studies further showed that the FMRP-GFP labeled granules also contained RNA, ribosomal subunits, kinesin heavy chain, and FXR1P molecules. This report is the first example of trafficking of RNA-containing granules with FMRP as a core constituent in living PC12 cells.